Lars Berlemann, Stefan Mangold

Cognitive Radio and Dynamic Spectrum Access

• Gebundenes Buch

Produktbeschreibung

Radio spectrum is today not efficiently utilized because of a complicated and time-consuming radio regulation processes and inflexibility in standardization. In this book, intelligent technologies to help overcome these barriers, namely, cognitive radios, are discussed. Written by two top researchers from this field, bringing their knowledge and expertise to readers, this book includes guidance towards applications of cognitive radio and dynamic spectrum access. It also includes a foreword and use cases from Joseph Mitola III, acknowledged as 'the inventor of Cognitive Radio'. All source code of authors' analysis will be available on accompanying website

The book covers:
The Problem: Spectrum Scarcity;
Today's Approaches for Spectrum Sharing;
Feature Detection and Spectrum Opportunity Identification;
Vertical Spectrum Sharing; Horizontal Spectrum Sharing;
Cognitive Radio for Mesh Networks and;
True Cognitive Radio

There are also three appendices on Software Tools, Analytical models and Game Theory.

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Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.

Produktdetails

• Verlag: Wiley & Sons
• 1. Auflage
• Seitenzahl: 242
• Erscheinungstermin: 2. März 2009
• Englisch
• Abmessung: 249mm x 173mm x 18mm
• Gewicht: 592g
• ISBN-13: 9780470511671
• ISBN-10: 0470511672
• Artikelnr.: 25625034

Autorenporträt

Lars Berlemann and Stefan Mangold both contribute to research programs, standardization and industry innovations in the field of dynamic spectrum access, cognitive radio, and IEEE 802 standards. Together they have filed numerous journal and magazine articles, patents, and contributions to research conferences and workshops. They both consult government organizations such as the European Commission in steering related research programs. Lars Berlemann and Stefan Mangold have been delivering tutorials on cognitive radio at various research conferences such as IEEE PIMRC and the European Wireless Conference. As alumni from RWTH Aachen University, Germany, Lars Berlemann and Stefan Mangold graduated at the Chair of Communication Networks, ComNets, with Professor Bernhard H. Walke as PhD advisor. Their PhD theses (both awarded summa cum laude) are today considered to be important early research contributions to the field and are in the highest ranks in the number of downloads from the University's download servers. Together with Professor Walke, Drs Berlemann and Mangold coedited the Wiley book IEEE 802 Wireless Systems: Protocols, Multi-Hop Mesh/Relaying, Performance and Spectrum Coexistence which was published in November 2006. Lars Berlemann is product manager in the product and innovation department of Deutsche Telekom, Germany. Stefan Mangold is manager at Swisscom, Switzerland, leading the access team of the product IT development group of Swisscom Network & IT. They both work for companies that operate mobile, fixed, and broadcast networks, and in addition provide services with excellent customer focus. Consequently, Drs Berlemann and Mangold understand and exploit the synergies between academic research focusing on excellence, and industry innovations focusing on commercial exploitation. Lars Berlemann and Stefan Mangold share and disseminate what they learn. In parallel with their employment, they enjoy working with students. Lars Berlemann is guest lecturer at the Chair of Communication Networks, Technical University of Dortmund, Germany. Stefan Mangold is with ETH Zurich, Switzerland, Department of Computer Science, where he works as lecturer and visiting scientist. In addition to his scientific engineering background, Lars Berlemann holds a diploma in Business and Economics from RWTH Aachen. The comments and statements made in this book are from the authors and do not necessarily reflect the official position of their employers.

Inhaltsangabe

List of Figures.
List of Tables.
About The Authors.
Foreword.
Acknowledgement.
Preface.
Abbreviations.
1. INTRODUCTION.
1.1 Access to radio spectrum.
1.2 Artificial spectrum scarcity from unexploited frequencies.
1.3 Cognitive radio and dynamic spectrum access as solution.
1.4 This book 28.
2. RADIO SPECTRUM TODAY - REGULATION AND SPECTRUM USAGE.
2.1 History and terminology.
2.1.1 The four basic approaches for radio spectrum regulation.
2.1.2 Guiding principles.
2.2 Institutions that regulate radio spectrum.
2.2.1 International Telecommunication Union, ITU.
2.2.2 Europe.
2.2.3 Germany.
2.2.4 United Kingdom.
2.2.5 Japan.
2.2.6 P.R. China.
2.2.7 United States of America.
2.3 Licensed and unlicensed spectrum.
2.3.1 The disadvantages of spectrum licensing.
2.3.2 Unlicensed spectrum as alternative.
2.3.3 Tragedy of commons in unlicensed spectrum.
2.3.4 Spectrum measurements.
3. RADIO SPECTRUM TOMORROW ? DYNAMIC SPECTRUM ACCESS & SPECTRUM SHARING.
3.1 Spectrum sharing and dynamic spectrum access: concepts and terminology.
3.1.1 Spectrum trading and spectrum liberalization.
3.1.2 Underlay and overlay spectrum sharing.
3.1.3 Vertical and horizontal spectrum sharing.
3.1.4 Coexistence, coordination and cooperation.
3.2 Horizontal spectrum sharing.
3.2.1 Coexistence.
3.2.2 Centralized spectrum coordination for horizontal sharing.
3.2.3 Spectrum sharing games.
3.3 Vertical spectrum sharing.
3.3.1 Re-use of TV bands for vertical spectrum sharing.
3.3.2 Spectrum pooling and a common control for vertical spectrum sharing.
3.3.3 Operator-assistance in vertical spectrum sharing.
3.3.4 Spectrum load smoothing for vertical spectrum sharing.
3.4 Taxonomy for spectrum sharing.
4. TOWARDS COGNITIVE RADIO - RESEARCH AND STANDARDIZATION.
4.1 Research programs and projects.
4.1.1 DARPA Next Generation Communications Program, XG.
4.1.2 National Science Foundation's project GENI.
4.1.3 European project E3.
4.1.4 European project WINNER+.
4.1.5 European project WIP.
4.1.6 European project SOCRATES.
4.1.7 European project ROCKET.
4.1.8 European project ORACLE.
4.2 IEEE coordination, and the Coexistence Advisory Group IEEE 802.19.
4.3 IEEE SCC41/P1900.
4.3.1 IEEE P1900.1.
4.3.2 IEEE P1900.2.
4.3.3 IEEE P1900.3.
4.3.4 IEEE P1900.4.
4.3.5 IEEE P1900.5.
4.4 Wi-Fi Wireless Local Area Networks IEEE 802.11.
4.4.1 IEEE 802.11k for radio resource measurements.
4.4.2 IEEE 802.11n for high throughput.
4.4.3 IEEE 802.11s for mesh networks.
4.4.4 IEEE 802.11y for high power Wi-Fi.
4.5 WiMAX Wirless Metropolitan Area Networks IEEE 802.16.
4.5.1 IEEE 802.16.2 Coexistence.
4.5.2 IEEE 802.16h license exempt.
4.5.3 IEEE 802.22 for wireless rural area networks.
4.6 Other standardization activities.
4.6.1 White Spaces Coalition & Wireless Innovation Alliance.
4.6.2 The New America Foundation and open spectrum.
4.6.3 SDR Forum.
4.6.4 Third Generation Partnership Project 3GPP.
4.6.5 European Telecommunications Standards Institute ETSI.
4.6.6 Academic research conferences and workshops.
5. PROPOSED ENABLERS FOR REALIZING HORIZONTAL SPECTRUM SHARING.
5.1 IEEE 802.11 in unlicensed spectrum.
5.1.1 Overview.
5.1.2 Physical layer.
5.1.3 Medium access control.
5.1.4 Learning from 802.11.
5.2 IEEE 802.16 in unlicensed spectrum.
5.2.1 Coexistence scenario.
5.2.2 Protecting the beginning of 802.16 MAC frame.
5.2.3 Protecting the 802.16 UL subframe.
5.2.4 Shifting the contention slots.
5.2.5 Quality-of-service, efficiency, and fairness.
5.3 Policies in spectrum usage.
5.3.1 Policy framework.
5.3.2 Spectrum navigation.
5.3.3 Reasoning based spectrum navigation.
5.4 Policy language.
5.5 Spectrum sharing games.
5.5.1 Related work.
5.5.2 802.11e coexistence scenario.
5.5.3 Game overview.
5.5.4 Single stage game for frame based interaction.
5.5.5 Quality-of-service as utility.
5.5.6 Analytic game model.
5.5.7 Behavior.
5.5.8 Equilibrium analysis.
5.5.9 Multi stage game model.
5.5.10 Discounting of future payoffs.
5.5.11 Strategies.
5.5.12 Nash equilibrium in multi stage games.
5.5.13 QoS evaluation of strategies.
5.5.14 Game approach as policy.
5.5.15 Learning from spectrum sharing games.
6. PROPOSED ENABLERS FOR REALIZING VERTICAL SPECTRUM SHARING.
6.1 Frequency division duplex for Wi-Fi: FDD WLANs.
6.2 Operator assisted cognitive radio with beaconing.
6.2.1 Existing standard beaconing concepts.
6.2.2 What is a beacon?
6.2.3 Improved signaling mechanism with dual beacons.
6.2.4 Beacon implementation in IEEE 802.11.
6.2.5 Evaluation.
6.2.6 Dual beaconing for the reuse of TV bands as policy.
6.3 Spectrum load smoothing.
6.3.1 Related work.
6.3.2 Enabling cognitive radios.
6.3.3 Spectrum load smoothing in the time domain.
6.3.4 Initial simulations and convergence experiments.
6.3.5 Modeling spectrum load smoothing in spectrum sharing scenarios.
6.3.6 QoS support in IEEE 802.11e coexistence scenarios.
6.3.7 SLS with reservations - approach to the re-use of TV-bands.
6.3.8 SLS without reservations - opportunistic spectrum usage scenario.
6.3.9 Evaluation of QoS capabilities.
6.3.10 Spectrum load smoothing as policy.
6.3.11 Learning from spectrum load smoothing approach.
7. OUR VISION ? THE TRUE COGNITIVE RADIO.
7.1 Mitola's cognition circle and related cognitive radio definitions.
7.2 Cognitive radios can gain from delay-tolerant software radio.
7.3 DARPA XG provides implementation guidelines, including the access
protocol.
7.3.1 Traceable decision making.
7.3.2 Machine-understandable radio semantics.
7.4 Spectrum etiquette may stimulate cognitive behavior.
7.4.1 What is spectrum etiquette?
7.4.2 Value orientation.
7.5 Network operators may assist dynamic spectrum access.
7.6 Business opportunities.
8 CONCLUDING REMARKS.
A. APPENDIX "JEMULA802".
B. APPENDIX "YOUSHI".
B.1 Modeling QoS requirements and demands.
B.2 Resource allocation and collisions.
B.3 Graphical user interface.
References.
Index.